A package board includes a stack structure that includes a circuit layer and a fiber layer. The fiber layer includes at least one first fiber that extends in a first direction and is a non-woven fiber. Also, a prepreg includes a first fiber that is a non-woven fiber; a plurality of second fibers that are spaced apart from the first fiber and are woven fibers; and an insulating layer that fills gaps between the first fiber and the plurality of second fibers.

The present invention relates to a thermoset resin composition, and a prepreg and a laminate for a printed circuit board manufactured therefrom. The thermoset resin composition comprises the following components: a phosphorus-containing polyphenyl ether resin having low molecular weight, an epoxy resin, a cyanate resin and an accelerator. The prepreg manufactured using the resin composition comprises a base material and the thermoset resin composition adhered to the base material by impregnation and drying. The laminate for a printed circuit board manufactured using the resin composition comprises a plurality of laminated prepregs, a metal foil covering one or two faces of the laminated prepregs by pressing, with each prepreg comprising a base material and the thermoset resin composition adhered to the base material by impregnation and drying. The thermoset resin composition of the present invention has properties such as a low dielectric constant and a dielectric dissipation factor, high heat resistance, a high glass transition temperature, and flame retardancy, etc. The laminates for a printed circuit board manufactured using same have excellent metal foil peel strength, heat resistance and dielectric properties, and are suitable for high frequency and high speed electronic circuit boards.

A manufacturing method for a component incorporated substrate according to the present invention includes positioning an electronic component with reference to a mark formed on a copper layer, the mark consisting of a material less easily etched than copper by a copper etching agent used for etching of copper, after mounting the electronic component on the copper layer with an adhesive layer interposed therebetween, embedding the electronic component and the mark in an insulating substrate, thereafter, etching and removing a part of the copper layer to form a window for exposing the mark, forming an LVH reaching a terminal of the electronic component with reference to the exposed mark, electrically connecting the terminal and the copper layer via a conduction via formed by applying copper plating to the LVH, and, thereafter, forming the copper layer into a wiring pattern.

A package board includes a stack structure that includes a circuit layer and a fiber layer. The fiber layer includes at least one first fiber that extends in a first direction and is a non-woven fiber. Also, a prepreg includes a first fiber that is a non-woven fiber; a plurality of second fibers that are spaced apart from the first fiber and are woven fibers; and an insulating layer that fills gaps between the first fiber and the plurality of second fibers.

Provided is a prepreg capable of attaining thermal expansion coefficient reduction and elastic modulus increase without increasing the filling ratio of an inorganic filler therein and/or without using a resin having a low thermal expansion coefficient, and thereby capable of reducing warpage thereof. Specifically, provided is a prepreg containing glass fibers and a thermosetting resin composition, and containing a layer of plural glass fiber filaments aligned to run nearly parallel to each other in one direction. Also provided are a production method for the prepreg, a laminate containing the prepreg and its production method, a printed circuit board containing the laminate, and a semiconductor package having a semiconductor device mounted on the printed circuit board.

A dielectric substrate comprises a resin composition impregnated with non-woven fibrous mat material having a thickness of 5 mils (127 micrometers), wherein the fibrous mat material comprises fibers, having a diameter of 1 nm to 10 m, that have been extruded through one or more openings to produce fibers that have been collected in the form of a fibrous non-woven mat, and wherein the fibers exhibit a multi-directional orientation in the non-woven mat material. The dielectric substrate is useful in circuit materials, circuits, and multi-layer circuits, economical to make, and has excellent electrical and mechanical properties.

Biodegradable printed circuit boards, or PCBs, may be produced from substrate sheets that include at least one biodegradable polymer. In addition, the electrical traces used on the PCBs, may also include a biodegradable polymer incorporated with an electrically conductive material. The PCBs may be composted to degrade the PCBs, and the

Dielectric materials including non-woven inorganic fabrics impregnated with a low-density resin are disclosed. The dielectric materials may have a thickness in a range of about 5 to about 125 microns for use in printed circuit boards.

The present invention provides a non-woven fabric prepreg, a metal-foil-clad plate and a printed circuit board. The non-woven fabric prepreg comprises a fluorine-containing resin binder non-woven fabric and a fluorine-containing resin composition, wherein the fluorine-containing resin binder non-woven fabric comprises a binder and inorganic fibers, and the binder is a fluorine-containing resin emulsion; and the fluorine-containing resin composition comprises, in parts by weight, 30-100 parts of a fluorine-containing resin emulsion, and 0-70 parts of an inorganic filler. The non-woven fabric prepreg and a copper-clad plate containing the non-woven fabric prepreg of the present invention have good dielectric properties and a low thermal expansion coefficient, such that the copper-clad plate can meet the performance requirements of the high-frequency communication field on a copper-clad plate material.

Dielectric materials including non-woven inorganic fabrics impregnated with a low-density resin are disclosed. The dielectric materials may have a thickness in a range of about 5 to about 125 microns for use in printed circuit boards.